The genetic basis of leaf lamina establishment and growth. This study will help reveal how the development of leaves is coordinated by tissue patterning genes and the plant growth hormone auxin. All plants grow in this way, and the findings, made using a model laboratory plant, will be applicable to crop species as well.
The evolution of the alternation of generations in land plants. This project aims to investigate how a genetic system, comprised of a homeodomain protein encoding gene family controlling the haploid to diploid transition, has evolved during land plant evolution.
The project expects to generate new knowledge concerning the evolution of land plants from which our food and fibre are derived.
The intended outcomes include an elucidation of how an ancestral genetic network was elaborated during the e ....The evolution of the alternation of generations in land plants. This project aims to investigate how a genetic system, comprised of a homeodomain protein encoding gene family controlling the haploid to diploid transition, has evolved during land plant evolution.
The project expects to generate new knowledge concerning the evolution of land plants from which our food and fibre are derived.
The intended outcomes include an elucidation of how an ancestral genetic network was elaborated during the evolution of a multicelluar organism, including the retention of ancestral functions and the origins of new functions.
An anticipated benefit is the ability to manipulate the the growth and development of plants based on fundamental principles, which has broad agricultural implications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100190
Funder
Australian Research Council
Funding Amount
$388,600.00
Summary
Tracing the Evolutionary History of Plant Developmental Mechanisms. Knowledge of the evolutionary history of genes involved in developmental processes provides a foundation for understanding how genetic networks were established and how their manipulation may influence plant growth and form. Genetic programs that direct growth and development in response to light will be examined functionally in Marchantia, a liverwort. Liverworts hold a key position in plant evolution as the sister group to all ....Tracing the Evolutionary History of Plant Developmental Mechanisms. Knowledge of the evolutionary history of genes involved in developmental processes provides a foundation for understanding how genetic networks were established and how their manipulation may influence plant growth and form. Genetic programs that direct growth and development in response to light will be examined functionally in Marchantia, a liverwort. Liverworts hold a key position in plant evolution as the sister group to all other land plants and possess many attributes reminiscent of the ancestral land plant. This project is expected to reveal some of the ancestral mechanisms for how light regulates plant form via the hormone auxin and could, in the future, aid the precise design of plants for diverse agricultural applications.Read moreRead less
The origin and evolution of the land plant meristem. This project aims to identify the extent of overlap between the genetic determinants of the gametophyte and sporophyte shoot meristems.
The project expects to generate new knowledge of the evolution and development of land plants by applying comparative genomics and new technologies to a novel model genetic system.
Expected outcomes include an elucidation of the genetic basis for one of the key morphological adaptations for life on land.
Th ....The origin and evolution of the land plant meristem. This project aims to identify the extent of overlap between the genetic determinants of the gametophyte and sporophyte shoot meristems.
The project expects to generate new knowledge of the evolution and development of land plants by applying comparative genomics and new technologies to a novel model genetic system.
Expected outcomes include an elucidation of the genetic basis for one of the key morphological adaptations for life on land.
The ability to manipulate the growth and development of plants via the activity of meristems based on fundamental principles has broad agricultural implications.
Read moreRead less
Evolution of the alternation of generations in the land plant life cycle. This project aims to investigate the genetic and evolutionary basis of land plants’ dimorphic life cycle where a single genome can generate two body plans. Like animals, land plants spend part of their life as a diploid, where meiosis generates haploid spores. Unlike animals, these spores grow into multicellular organisms before generating gametes. The project will study a homeodomain protein encoding a gene family that co ....Evolution of the alternation of generations in the land plant life cycle. This project aims to investigate the genetic and evolutionary basis of land plants’ dimorphic life cycle where a single genome can generate two body plans. Like animals, land plants spend part of their life as a diploid, where meiosis generates haploid spores. Unlike animals, these spores grow into multicellular organisms before generating gametes. The project will study a homeodomain protein encoding a gene family that controls the haploid to diploid transition in unicellular algae and fungi. It will investigate land plant genes in a flowering plant and a liverwort. These findings could help scientists understand and manipulate important processes such as pollen and seed production.Read moreRead less
Evolution of vascular tissue in land plants. This project will investigate genetic mechanisms of secondary cell wall thickening in a new genetic model representing an ancient plant lineage. This research will reveal the evolutionary origin of plant vascular tissue; a significant innovation that allowed increased size of plants and the origin of wood.
Decoding tissue-specific components of cereal grain development. This project aims to investigate how barley flowers produce cells that deliver nutrients into developing seeds. This project expects to generate new knowledge through international collaboration and technical improvements in cell biology and genetics, overcoming current methodological limitations to precisely influence seed size, shape and quality, which are traits of agricultural relevance to the Australian cereal industry. Expect ....Decoding tissue-specific components of cereal grain development. This project aims to investigate how barley flowers produce cells that deliver nutrients into developing seeds. This project expects to generate new knowledge through international collaboration and technical improvements in cell biology and genetics, overcoming current methodological limitations to precisely influence seed size, shape and quality, which are traits of agricultural relevance to the Australian cereal industry. Expected outcomes include strengthened international partnerships, leveraged funding and increased knowledge of plant reproduction. This should provide significant benefits, including upskilled researchers, improved research capacity and genetic targets to optimise seed production in challenging climatic conditions. Read moreRead less
Activating the female germline during plant development. This project aims to investigate the mechanistic basis for female germline formation in two plant species including barley, which is of agricultural relevance to Australia. This project’s approach will integrate novel regulatory genes and data from Arabidopsis and barley. This knowledge will provide significant benefits, such as novel reproductive strategies for crop improvement.
How SEP-like genes determine cereal inflorescence architecture. This project aims to understand the morphological diversity of inflorescence architecture between cereal crop species. To do so, this project will identify functions and analyse the regulatory networks of conserved SEPALLATA genes (SEPs). This will enable them to determine cereal inflorescence morphogenesis of rice (branching) and barley (non-branching), representing the most important cereals. Identifying and understanding rice and ....How SEP-like genes determine cereal inflorescence architecture. This project aims to understand the morphological diversity of inflorescence architecture between cereal crop species. To do so, this project will identify functions and analyse the regulatory networks of conserved SEPALLATA genes (SEPs). This will enable them to determine cereal inflorescence morphogenesis of rice (branching) and barley (non-branching), representing the most important cereals. Identifying and understanding rice and barley SEPs, their direct targets and interactors, and how they regulate inflorescence branches and spikelets in both species is expected to provide evolutionary and developmental insights and targets to improve for crop yield. A molecular understanding of the regulatory network that underpins inflorescence shape and grain number will advance fundamental biology, and could form the basis for significant yield improvements by manipulating key points in the developmental pathway.Read moreRead less